Comparison of Neck Injury Criteria Values Across Human Body Models of Varying Complexity

Johnson, Dale E.; Koya, Bharath; Gayzik, F. Scott

doi:10.3389/fbioe.2020.00985

Cited by 3 publications

(2 citation statements)

References 35 publications

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“…It quantifies the relationship between upper neck forces and moments and the associated risk of injury. The calculation of Nij is shown below in the equation as a combination of axial force and moment in the sagittal plane, normalized by the critical intersection point of axial force and the intersection point of moment in the sagittal plane (Johnson et al, 2020).…”

Section: The Impact Of Drone-human Collisions 51 Tools For Assessing ...mentioning

confidence: 99%

The Multidimensional Threats of Unmanned Aerial Systems: Exploring Biomechanical, Technical, Operational, and Legal Solutions for Ensuring Safety and Security

Perz

2024

AoT

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Unmanned Aerial Vehicles (UAVs), also referred to as drones, are increasingly utilized in sectors such as surveillance, transportation, and entertainment. The global UAV market, projected to escalate to USD 70.7 billion by 2026, demonstrates a significant growth trajectory. However, alongside their functional utility, UAVs present substantial risk factors, notably in the domain of collisions with humans and other entities. These collision events are categorizable by operational context (military versus civilian) and flight phase (e.g., takeoff, landing). Contributory factors to these occurrences include operator errors, equipment malfunctions, and prevailing environmental conditions. Incidents involving human-UAV collisions are of particular concern. The severity of impact is contingent upon UAV specifications and the conditions of operation. Predominantly accidental, these incidents accentuate escalating safety concerns in the burgeoning UAV sector. This manuscript endeavors to examine the risks inherent in UAV operations, with an emphasis on human-UAV collision scenarios. A review of extant literature is conducted to formulate safety measures and amplify awareness regarding UAV-associated hazards. The manuscript is methodically structured to encompass scenarios of hazard within UAV operations, historical accounts of collisions, and an analysis of their causative factors and subsequent ramifications. Additionally, it scrutinizes the legislative framework governing UAV operations on a global scale, with a specific focus on Europe and Poland. The discourse extends to the examination of physical impacts resultant from UAV-human collisions, exploring diverse scenarios and resultant injuries. The conclusion delineates the necessity for a comprehensive understanding of UAV-associated risks and advocates for strategies to mitigate collision risks. With UAVs becoming increasingly integrated into everyday functionalities, addressing potential threats assumes critical importance. Achieving equilibrium between technological advancement and public safety is paramount. Effective regulation of UAVs necessitates a multifaceted approach, incorporating legal and procedural constraints to curtail accident rates. The manuscript underscores the imperative for established weight and height thresholds for UAVs, implementation of protective measures, and enhancement of public cognizance. Further investigative efforts are imperative to elucidate the long-term repercussions of UAV-induced injuries and the risks posed by emerging UAV models, underscoring the importance of responsible UAV utilization and the ongoing necessity for research in this domain.

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Section: The Impact Of Drone-human Collisions 51 Tools For Assessing ...mentioning

confidence: 99%

The Multidimensional Threats of Unmanned Aerial Systems: Exploring Biomechanical, Technical, Operational, and Legal Solutions for Ensuring Safety and Security

Perz

2024

AoT

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“…Therefore, they are preferred over ATD finite element models in such scenarios. When it comes to developing criteria for neck injuries, measuring the stress and strain that muscles and tissue ligaments can withstand is crucial [ 17 , 18 , 19 , 20 ]. Advanced neck finite element modeling can provide dynamic responses of the system that are not possible with equivalent multibody models.…”

Section: Introductionmentioning

confidence: 99%

Efficient 2D Neck Model for Simulation of the Whiplash Injury Mechanism

Henriques,

Martins,

Carvalho

2024

Bioengineering

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Whiplash injuries, mainly located in the neck, are one of the most common injuries resulting from road collisions. These injuries can be particularly challenging to detect, compromising the ability to monitor patients adequately. This work presents the development and validation of a computationally efficient model, called Efficient Neck Model—2D (ENM-2D), capable of simulating the whiplash injury mechanism. ENM-2D is a planar multibody model consisting of several bodies that model the head and neck with the same mass and inertia properties of a male occupant model in the 50th percentile. The damping and non-linear spring parameters of the kinematic joints were identified through a multiobjective optimization process, solved sequentially. The TNO-Human Body Model (TNO-HBM), a validated occupant model for rear impact, was simulated, and its responses were used as a reference for validation purposes. The root mean square (RMS) of the deviations of angular positions of the bodies were used as objective functions, starting from the bottom vertebra to the top, and ending in the head. The sequence was repeated until it converged, ending the optimization process. The identified ENM-2D model could simulate the whiplash injury mechanism kinematics and accurately determine the injury criteria associated with head and neck injuries. It had a relative deviation of 8.3% for the head injury criteria and was 12.5 times faster than the reference model.

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Numerical investigation of driver injury risks in car-to-end terminal crashes using a human finite element model

Meng,

Buckland,

Untaroiu

2024

Computer Methods in Biomechanics and Biomedical Engineering

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Comparison of Neck Injury Criteria Values Across Human Body Models of Varying Complexity

Cited by 3 publications

References 35 publications

The Multidimensional Threats of Unmanned Aerial Systems: Exploring Biomechanical, Technical, Operational, and Legal Solutions for Ensuring Safety and Security

The Multidimensional Threats of Unmanned Aerial Systems: Exploring Biomechanical, Technical, Operational, and Legal Solutions for Ensuring Safety and Security

Efficient 2D Neck Model for Simulation of the Whiplash Injury Mechanism

Numerical investigation of driver injury risks in car-to-end terminal crashes using a human finite element model

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